Classifications

• • H—ELECTRICITY
  • H03—ELECTRONIC CIRCUITRY
  • H03F—AMPLIFIERS
  • H03F3/00—Amplifiers with only discharge tubes or only semiconductor devices as amplifying elements
  • H03F3/45—Differential amplifiers
  • H03F3/45071—Differential amplifiers with semiconductor devices only
  • H03F3/45479—Differential amplifiers with semiconductor devices only characterised by the way of common mode signal rejection
  • H03F3/45632—Differential amplifiers with semiconductor devices only characterised by the way of common mode signal rejection in differential amplifiers with FET transistors as the active amplifying circuit
  • H03F3/45636—Differential amplifiers with semiconductor devices only characterised by the way of common mode signal rejection in differential amplifiers with FET transistors as the active amplifying circuit by using feedback means
  • H03F3/45641—Measuring at the loading circuit of the differential amplifier
  • H03F3/45654—Controlling the active amplifying circuit of the differential amplifier

Definitions

• the invention relates to a device containin * ⁇ g> ' a functional circuit with a differential output.
• a circuit with a differential output for example an op amp, delivers its output signal as the difference between the potentials or currents on two output connections.
• a circuit with a single ended output delivers its output as a potential relative to a supply connection.
• a circuit with a differential output provides improved substrate and supply noise rejection, added dynamic range and systematic offset cancellation or reduction.
• the common mode potential of the differential output that is, the average of the potentials on the two output connections has no significance for the output signal. However, to ensure proper operation of the circuit, the common mode potential should be kept near some set potential.
• a common mode feedback circuit is commonly used to regulate the common mode of the differential output.
• Johns and Martin disclose a common mode feedback circuit comprising two differential pairs, each containing a current source and a first and second IGFET, the gate of the first IGFET in each pair being coupled to a respective one of the connections of the differential output, the gate of the second mosfet being coupled to a reference potential.
• IGFETs Insulating Gate Field Effect Transistors are also commonly referred to as MOSFETs: Metal Oxide Silicon Field transistors, which is taken to include FETS with any kind of gate electrodes, also poly-silicon gate electrodes).
• MOSFETs Metal Oxide Silicon Field transistors
• This common mode feedback circuit operates properly only as long as the potentials of the connections of the differential output are within the operating range of the differential pairs, that is, more than a IGFET threshold plus a current source saturation voltage away from a power supply potential. Typically this means that 1.2 Volt of the potential range between the power supply potentials cannot be used for the potentials at the differential output. For circuits with a low power supply range this is a significant limitation.
• the common mode feedback circuit comprises
• the connections of the differential output being coupled to the backgate so as to have an influence on current through the channel dependent on the common mode.
• the sum the influences is used to feedback the common mode to the common mode control input.
• the IGFETs When a varying potential is applied to the backgate, the IGFETs remains operational over a wider range than when that potential is applied to the gate of an IGFET. Hence, the common mode feedback circuit is operational over a wider range.
• the gate of the IGFET is connected to one of the power supply connections, so that the IGFET is operational over as large a range of potentials as possible.
• the currents through the IGFETs are summed and used to determine a current supplied to the common mode adjustment input of the functional circuit, for example using current mirror techniques and/or by providing a current path from the channels of the IGFETs to the adjustment input.
• a current supplied to the common mode adjustment input of the functional circuit for example using current mirror techniques and/or by providing a current path from the channels of the IGFETs to the adjustment input.
• the common mode feedback exhibits a residual dependence on the differential output voltage.
• the residual dependence may be reduced by using additional IGFETs with their backgates coupled to the connections of the differential output, so that the common mode potential has a further influence on the current through their channels, in such a way that the current through the additional IGFETs has a compensating effect on the residual effect of the earlier mentioned IGFETs.
• Figure 1 shows an op-amp with a differential output and a common mode feedback circuit
• Figure 2 shows a first embodiment of a common mode feedback circuit
• Figure 3 shows a first alternative for the common mode feedback circuit
• Figure 4 shows a graph produced by simulation of the circuit of fig 1 and 3.
• Figure 5 shows a further embodiment of the common mode feedback circuit.
• Figure 6 shows simulations of the circuit of figure 5
• Figure 7 shows an example of a further common mode feedback circuit
• Figure 8 shows the result of a simulation of the circuit of figure 7.
• Figure 9 shows a further embodiment of the common mode feedback circuit.
• Figure 10 shows another embodiment of the common mode feedback circuit.
• Figure 1 shows an example of an op-amp with a differential output and a common mode feedback circuit.
• the circuit has supply connections Vcc and Vee.
• the op-amp contains a differential pair containing a first and second PMOS transistors 12a,b with common source connections and a current source 10 connected between the common source connections and the Vcc supply connection.
• the op-amp contains a first and second current folding branch connected between the supply connections Vee and Vcc and each containing successively a node 15a,b, a channel of an NMOS transistor 14a,b, connection of the differential output 16a,b, a current source 16a,b and the power supply connection Vcc.
• the drains of the first and second current source are each connected to nodes 15a,b of a respective one of the two current folding branches.
• the gates of the first and second NMOS transistor are connected to a bias voltage connection VB.
• a common mode feedback circuit 18 is connected between the connections 17a,b of the differential output and the current folding branches.
• the control circuit has inputs coupled to the differential output connections 17a,b.
• the common mode feedback circuit has controllable current sources outputs 19a,b.
• the controllable current source outputs 19a,b are each also part of a respective one of the current folding branches, each connected to a respective one of the nodes 15a,b so as to supply a current with a high impedance.
• MOS transistors.210a,b are shown inside the common mode feedback circuit 18 .
• the connections 17a,b of the differential output are each connected to the backgate of a respective one of the MOS transistors 210a,b.
• Further circuitry (not shown in figure 1) couples the MOS transistors 210a,b to the controllable current source outputs 19a,b. In operation, input potentials are applied to the gates of the PMOS transistors
• the input potentials control PMOS the distribution of the current from the current source 10 of the differential pair over the PMOS transistors.
• the fold-back branches serve to pass this distribution to the connections 17a,b of the differential output.
• Equal currents are supplied to the current folding branches by the current sources 16a,b and the controllable current outputs 19a,b.
• the difference between currents supplied by the PMOS transistors 12a,b in the differential pair determines the difference between the currents at the connections 17a,b of the differential output.
• the first and second NMOS transistor 14a,b serve as a cascode to isolate the nodes 15a,b from potential changes at the connections 17a,b of the differential output.
• the common mode feedback circuit 18 serves to keep the common mode potential of the connections 17a,b (half their sum) substantially at a predetermined potential.
• the common mode feedback circuit 18 senses the difference between a reference potential and the common mode of the potentials of the connections 17,b of the differential outputs.
• the common mode feedback circuit 18 adjusts the currents through the connections 17a,b of the differential output in proportion to that difference. This results in a negative feedback loop, which keeps the common mode of the differential output substantially at the reference potential.
• the common mode feedback circuit 18 adjusts the current through the connections 17a,b of the differential output via the current foldback branches. Because current sources are connected at all terminals of the current fold- back branches, the current supplied by the common mode feedback circuit 18 has to flow to the connections 17a,b of the differential output.
• the common mode feedback circuit 18 is arranged so that it supplies the same current from both controllable current source outputs 19a,b. When the common mode potential of the differential output is equal to a desired reference potential, the common mode feedback circuit 18 ensures that there is substantially no net common mode current at the differential output.
• the current outputs 19a,b supply "quiescent" currents whose sum is substantially equal to the sum of the currents from the current source 10 of the differential pair and the current sources 16a,b of the current foldback branches.
• the currents from the current outputs 19a,b are varied in proportion to the deviation.
• the invention is not limited to the particular configuration shown in figure 1.
• Any path for connecting the drains of the transistors of the differential pair to the differential output may be used.
• more elaborate input circuits may be used.
• the circuit need not even be a differential amplifier, any circuit with a differential output will do.
• the essential point is that a common mode feedback circuit is included which regulates the common mode component of the signal at the output of the circuit.
• the common mode feedback circuit 18 keeps operating when the potentials of the connections of the differential output vary over a wide range. For this reason, the potential of the connections 17a,b of the differential output influence the common mode feedback circuit 18 via the back-gate of MOS transistors 210a,b. Via the back gate, the potential of the connections 17a,b of the differential output influence the current flowing through the channel of the MOS transistors 210a,b and/or the voltage across the channel and this current and/or voltage is used to control adjustment of the currents supplied by the controllable differential current source output.
• the back-gate for this purpose a wide operating range is obtained; the only condition on the operating range is that the junction diodes from the source and drain to the back-gate are kept out of conduction.
• the common mode feedback circuit 18 can handle potentials of the connections 17a,b of the differential output over nearly the entire supply voltage range.
• the potential should be below a potential approximately 500mV above the lowest of the source drain voltages and if these source drain voltages are kept near Vcc a wide operating range is realized).
• Various circuits may be used to control the currents through the controllable current outputs 19a,b as a function of the current and/or voltage across the MOS transistors 210a,b. In the following a number of such circuits will be disclosed.
• Figure 2 shows a first embodiment of the common mode feedback circuit 18 according to the invention.
• the common mode feedback circuit of figure 2 contains a sensing circuit 20, 21a,b, a current control circuit 23 and identical first, second and third controllable current source 22a-c.
• the first and second controllable current source 22a,b have outputs connected to the first and second current source output 19a,b respectively.
• the sensing circuit of figure 2 contains a common current source 20 whose outputs forks over a sense branch 21a and a reference branch 21b.
• the sense branch has an output coupled to the supply voltage connection Vee
• the reference branch has an output coupled to an output of the third controllable current source 22c and to the current control circuit 23.
• the current control circuit has an output coupled to control inputs of the first, second and third controllable current source 22a-c.
• the sense branch contains a first and second current branch 25a-b.
• the reference branch contains a third current branch 25c.
• Each current branch 25a-c contains a series connection of the channel of a first and second PMOS transistor 210a-c, 212a-c.
• the gates of the transistors 210a-c, 212a-c are connected to the power supply connection Vee.
• the current control circuit 23 contains a current source 230 coupled to the first node via the channel of an NMOS transistor 232.
• the gate of NMOS transistor 232 is coupled to the bias voltage connection VB.
• a second node between the current source 230 and the channel of NMOS transistor 232 is coupled to a control input of the first second and third controllable current source 22a-c.
• the back-gate of the first PMOS transistors 210a-b in the first and second current branch 25a-c are connected to the first connection 17a of the differential output and the second connection 17b of the differential output.
• the drains of the first PMOS transistors 210a,b in the first and second current branch 25a-b are mutually connected.
• the back-gate of the first PMOS transistor 210c in the reference branch 21b is connected to a reference potential.
• the current sources 16a,b in the current fold-back branches of figure 1 each supply a current I and that the current source 10 of the differential pair supplies a current 21.
• the common current source 20 supplies a current 31 and the current source 230 of the current control circuit 23 supplies a current I.
• the current through the reference branch 21b will be called Y.
• the current control circuit 23 serves to ensure that the currents supplied by the first, second and third controllable current sources 22a-c are each substantially equal to I+Y.
• the sum of the currents supplied to nodes 15a,b is now 21 (from the current source 10 of the differential pair) plus 21 (from the current sources 16a,b in the current folding branches) minus 2(I+Y) (from the current source outputs 19a,b of the common mode feedback circuit 18), that is 2(1- Y).
• the common mode potential of the connections of the differential output will be steady only when this sum is zero.
• Figure 3 shows a first alternative for the common mode feedback circuit.
• the difference with the circuit of figure 2 is that the first and second current branch are not connected to the supply node Vee, but to the output of the first and second controllable current source 22a,b respectively.
• the current control circuit 23 contains an additional current source 234 connected to the first node between the reference current branch 21b and the third controllable current source 22c.
• the currents from the first and second current branches 25a,b will contribute to the net current at the outputs 19a,b of the controllable current source.
• the currents from the first and second current branches 25a,b will be equal, each (3I-Y)/2, because the second PMOS transistors 212a,b in the first and second current branches 21a-b are equal and have equal terminal voltages.
• the additional current source 234 supplies a current I in order to force an increase in the output current of the controllable current sources 22a-c by I to 2I+Y.
• the net current at each output node is (I+3Y)/2.
• the sum of the currents supplied to nodes 15a,b is now 21 (from the current source 10 of the differential pair) plus 21 (from the current sources 16a,b in the current folding branches) minus I+3Y (from the current source outputs 19a,b of the common mode feedback circuit 18), that is 3(1- Y).
• circuit of figure 3 increases the sensitivity of the net output current at the output node with respect to the current Y in the current branch 25c to 3Y as compared to 21 in figure 2.
• the third controllable current source 22c might differ from the first and second controllable current source, so as to create a current amplification (or reduction) factor; a different current might be supplied by the common current source 20, by the current sources 16a,b in the foldback branches, by the current source 10 the differential pair or by the current source or sources in the control circuit.
• a different current might be supplied by the common current source 20, by the current sources 16a,b in the foldback branches, by the current source 10 the differential pair or by the current source or sources in the control circuit.
• What matters is only the net common mode current supplied to the connections 19a,b of the differential output. This net current should be affected by the common mode potential of these connections 17a,b and the various current sources should be chosen such that their sum gives rise to a net current that is zero when this common mode potential is approximately at the desired common mode potential.
• Figure 4 shows a graph produced by simulation of the circuit of fig 1 and 3.
• the graph depicts the differential output voltage and the common mode output potential as a function of the differential input voltage at the gates of the transistors 12a,b of the differential pair.
• the common mode output potential is seen to be substantially constant when the differential output voltage range over a wide range. A deviation occurs for larger differential voltage, because in this case the decrease in current in one of the current branches 25a,b does not exactly compensate the increase in current in the other current branch 25a,b do to non- linearity.
• Figure 5 shows a further embodiment of the common mode feedback circuit.
• an additional PMOS transistor 214a-c has been added to each of the current branches 25a-c.
• the channel of the additional PMOS transistor 214a-c has been inserted between the channels of the first PMOS transistor 210a-c and second PMOS transistor 212a-c.
• the back gate of the additional PMOS transistor 214a-b in the first and second branch are coupled to the connections 17a,b of the differential output, but in each current branch 21a-c to a different one of these connection 17a,b than the first PMOS transistor 210a,b in the same current branch.
• the drains of the additional PMOS transistors 214a,b in the first and second current branch have been connected; unlike figure 4 there is no connection between the drains of the first PMOS transistors 210a,b in these current branches 21a,b.
• the backgates of both the first transistor 210c and the additional transistor 214c are coupled to the reference potential.
• the common mode feedback circuit 18 of figure 5 operates similar to that of figure 2 or 3.
• Figure 6 shows simulations of the circuit of figure 5. It is seen that the slight dependence of the common mode potential on the differential output voltage is different from that of figure 3. Instead of a small rise in common mode potential for larger differential output voltages, there is a small drop.
• a connection between the drains of the first PMOS transistors 210a,b in the first and second current branch 25a,b may be added. It has been found that this connection changes the small drop of figure 6 into a small rise.
• Two or more sets of current branches 25a-c may be combined into one common mode feedback circuit 18.
• the dependencies on the differential output voltage produced by the sets of current branches are added. If dependencies on the differential output voltage are opposite (a rise and a drop respectively) the resulting dependence will be smaller than that of the combined current branches.
• FIG. 7 shows an example of such a common mode feedback circuit 18 which combines two sets of current branches 25a-f.
• Each current branch contains the channels of three PMOS transistors 210a-f, 214a-f and 212a-f.
• the back gates of the first transistor 210a-f and the additional transistor 214a-f in each current branch 25a-f are connected to each other.
• In the first current branch of each set these backgates are connected to a first one 17a of the connections of the differential output.
• In the second current branch of each set these backgates are connected to a second one 17b of the connections of the differential output.
• In the third current branch of each set these backgates are connected to a reference potential.
• the difference between the two sets 25a-c, 25a-f lies in the connections between the drains of the PMOS transistors 210a-f, 214a-f of different current branches 21a-f.
• the first set 21a-c only the drains of the first PMOS transistors 210a,b of the first two current branches are connected.
• the second set 21d-f both the drains of the first PMOS transistor 210d,g and the drains of the additional PMOS transistor 214d,g are mutually connected.
• Figure 8 shows the result of a simulation of the circuit of figure 7. It is seen that the dependence of the common potential on the differential output voltage is reduced.
• FIG. 9 shows a further embodiment of the common mode feedback circuit 18.
• This circuit 18 contains two sets of current branches 25a-c, 25d-f, each with its own common current source 20, 29. Outputs of the sets of current branches are connected together to a controlled current mirror 27, which reflects the sum of the currents through the output branches to the controlled current outputs 19a,b.
• the current branches 25a-f are arranged in each set as a current mirror, which reflects the current drawn by one branch 25b,e into the other two branches 25a,c,d,f of the set.
• the degree of equality of the reflection is influenced by the potential of the connections 17a,b of the differential output.
• the first set contains a first branch 21a with a mirror transistor 210a having a back-gate connected to a first one of the connections 17a of the differential output.
• a first branch 21d has a mirror transistor 210d with a back-gate connected to a second one of the connections 17b of the differential output.
• a third branch 21c of the first and second set has a mirror transistor 210c with a back-gate connected to a reference potential. The output of these third branches is connected to input of the controlled current mirror 27.
• the common current sources 20, 29 both supply a current 31.
• the input branch of the current mirror in each set of current branches draws a current I.
• the first and third branch 21a,c,d,f in both sets 21a-c, 21d-f draw equal currents I and the controllable current source outputs 19a,b reflect a current 21.
• FIG. 10 shows another embodiment of the common mode feedback circuit 18.
• This common mode feedback circuit contains two sets 102a,b, 102c,d of two current branches, a reference branch and a sense branch. Each set has its own common current source 100a,b coupled to a supply node Vee via the two branches 102a-d in parallel. Each current branch contains the channel of a PMOS transistor 104a-d. The gates of the PMOS transistors 104a-d are connected to the supply connection Vee.
• the backgate of the PMOS transistors 104a,c in the sense branches of the respective sets are connected to the respective ones of the connections 17a,b of the differential output.
• the backgates of the PMOS transistors 104b,d in the reference branches are connected to a reference potential Vref.
• the circuit contains a first, second and third controllable current sources 106a- c.
• the first and second controllable current source 106a,b are connected to respective ones of the outputs 19a,b of the common mode feedback circuit 18.
• the third current source 106c is connected between the channels of the PMOS transistor 104b,d in the reference branches and the supply connection Vee.
• the control inputs of the controllable current sources 106a-c are connected to each other and to a node between the third controllable current source 106c and the channels of the PMOS transistors 104b,d in the reference branches.
• the common current sources 100a,b supply a fixed current 21 and the reference branches draw variable currents which will be called Yl and Y2 respectively.
• the controllable current sources 106a-c draw a current equal to the sum Y1+Y2 of the currents through the reference current branches.
• the net common mode current at the connections to the differential outputs is 4I-2*(Y1+Y2).
• the common mode feedback circuit 18 will regulate this net common mode current to zero, i.e. it will adjust the current until the potential of the backgates of the PMOS transistors 104a,c so that Y1+Y2 is equal to I.
• the potentials of the-connections 17a,b of the differential outputs control the currents through the transistors to whose backgates they are connected. These currents determine the common mode current feedback to the differential output.
• the feedback circuit responds to variations in the sum of these currents by applying proportional variations in the common mode current supplied to the connections of the differential output.
• the feedback circuit regulates the common mode output potential.

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• 1998
  • 1998-11-02 US US09/184,528 patent/US6118341A/en not_active Expired - Lifetime
• 1999
  • 1999-10-18 JP JP2000580300A patent/JP4665112B2/ja not_active Expired - Fee Related
  • 1999-10-18 EP EP99955856A patent/EP1046225A1/en not_active Withdrawn
  • 1999-10-18 WO PCT/EP1999/007923 patent/WO2000027029A1/en not_active Application Discontinuation

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